DFRobot Stepper Motors

Results: 3
Type
-HybridHybrid Gear Motor
Voltage - Rated
2.7VDC3.4VDC12VDC
Step Angle
1.8°18°
Accuracy
±5%-
Torque - Holding (oz-in / mNm)
48.6 / 343.19-
Size / Dimension
-Square - 1.654" x 1.654" (42.00mm x 42.00mm)
Diameter - Shaft
0.118" (3.00mm)0.197" (5.00mm)0.315" (8.00mm)
Length - Shaft and Bearing
0.394" (10.00mm)0.787" (20.00mm)0.945" (24.00mm)
Mounting Hole Spacing
1.100" (28.00mm)1.220" (31.00mm)-
Termination Style
ConnectorWire LeadsWire Leads with Connector
Operating Temperature
-20°C ~ 50°C-
Coil Resistance
1.5 Ohms2 Ohms30 Ohms
Features
-Flatted ShaftRound Shaft
Stocking Options
Environmental Options
Media
Marketplace Product
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Mfr Part #
Quantity Available
Price
Series
Package
Product Status
Type
Coil Type
Voltage - Rated
Current Rating (Amps)
Steps per Revolution
Step Angle
Accuracy
Torque - Holding (oz-in / mNm)
Size / Dimension
NEMA Frame Size
Diameter - Shaft
Length - Shaft and Bearing
Mounting Hole Spacing
Termination Style
Operating Temperature
Coil Resistance
Features
FIT0503
FIT0503
GEARMOTOR 12V MICR METAL STEPPER
DFRobot
39
In Stock
1 : ¥53.41000
Bulk
-
Bulk
Active
-
-
12VDC
-
-
18°
-
-
-
-
0.118" (3.00mm)
0.394" (10.00mm)
-
Wire Leads with Connector
-
30 Ohms
-
FIT0278
FIT0278
HYBRID STEPPER MOTOR FOR 3D PRIN
DFRobot
83
In Stock
1 : ¥118.59000
Bulk
-
Bulk
Active
Hybrid
Bipolar
3.4VDC
1.7 A
200.0
1.8°
±5%
48.6 / 343.19
Square - 1.654" x 1.654" (42.00mm x 42.00mm)
17
0.197" (5.00mm)
0.945" (24.00mm)
1.220" (31.00mm)
Connector
-20°C ~ 50°C
2 Ohms
Round Shaft
FIT0349
FIT0349
BIPOLAR STEPPER MOTOR WITH PLANE
DFRobot
15
In Stock
1 : ¥332.00000
Bulk
-
Bulk
Active
Hybrid Gear Motor
Bipolar
2.7VDC
-
-
1.8°
±5%
48.6 / 343.19
Square - 1.654" x 1.654" (42.00mm x 42.00mm)
17
0.315" (8.00mm)
0.787" (20.00mm)
1.100" (28.00mm)
Wire Leads
-20°C ~ 50°C
1.5 Ohms
Flatted Shaft
Showing
of 3

DFRobot Stepper Motors

Stepper motors are DC voltage motion actuators that move in discrete steps. Multiple sets of coils organized in groups called "phases" determine the motors armature position. Energizing each phase in sequence causes armature rotation one step at a time. With computer or microcontroller managed stepping, precise positioning and/or speed control is achieved. Steppers are selected by torque, steps per revolution, step angle, NEMA frame size, coil resistance, polarity and shaft features.